Patent application number | Description | Published |
20080251827 | Checkerboard deep trench dynamic random access memory cell array layout - A checkerboard deep trench dynamic random access memory cell array layout is disclosed, which includes a substrate, a plurality of gate conductor lines disposed on the substrate, a plurality of checkerboard-arranged and staggered deep trench capacitor structures embedded in the substrate under the gate conductor lines, and a plurality of active areas formed in the substrate under the gate conductor lines, alternatively arranged with the deep trench capacitor structures, and electrically connected with an adjacent deep trench capacitor structure. The width of the parts of the gate conductor lines above the deep trench capacitor structures is narrower than that of the parts of the gate conductor lines above the active areas. | 10-16-2008 |
20080277709 | DRAM STRUCTURE - A DRAM structure includes a substrate, a MOS transistor, a deep trench capacitor, a surface strap positioned on the surface of the substrate and interconnecting a drain of the MOS transistor and an electrode of the deep trench capacitor, wherein the sidewall and the top surface of the surface strap are covered with an insulating layer. A passing gate is positioned on the insulating layer. | 11-13-2008 |
20080299734 | Method of manufacturing a self-aligned fin field effect transistor (FinFET) device - A method of manufacturing a self-aligned fin FET (FinFET) device is disclosed, in which, an insulating layer of a shallow trench isolation is etched back to partially expose sidewalls of the semiconductor substrate surrounded by the shallow trench isolation, and the sidewalls of the semiconductor substrate are then isotropically etched, allowing the semiconductor substrate to form into a relatively thin fin structure for forming a three-dimensional gate structure having three faces. | 12-04-2008 |
20080305605 | METHOD FOR FORMING SURFACE STRAP - A method for forming a surface strap includes forming a deep trench capacitor having a conductive connection layer on its surface in the substrate and the conductive connection layer in contact with the conductive layer; forming a poly-Si layer covering the pad layer and the conductive connection layer; performing a selective ion implantation with an angle to make part of the poly-Si layer an undoped poly-Si layer; removing the undoped poly-Si layer to expose part of the conductive connection layer; etching the exposed conductive connection layer to form a recess; removing the poly-Si layer to make the exposed conductive connection layer a conductive connection strap; filling the recess with an insulation material to form a shallow trench isolation; exposing the conductive layer; and selectively removing the conductive layer to form a first conductive strap which forms the surface strap together with the conductive connection strap. | 12-11-2008 |
20080318377 | METHOD OF FORMING SELF-ALIGNED GATES AND TRANSISTORS - Method for fabricating a self-aligned gate of a transistor including: forming a plurality of deep trench capacitors in a substrate, concurrently forming a surface strap and a contact pad on a surface of the substrate, wherein a spacing between the surface strap and the contact pad exposes a portion of an active area, filling the spacing with a dielectric layer, forming a photoresist pattern on the substrate, wherein the photoresist has an opening situated directly above the spacing between the surface strap and the contact pad, etching away the dielectric layer and a portion of a shallow trench isolation region through the opening thereby forming an upwardly protruding fin-typed channel structure, forming a gate dielectric layer on the upwardly protruding fin-typed channel structure, and forming a gate on the gate dielectric layer. | 12-25-2008 |
20090001457 | Semiconductor structure - The present invention discloses a semiconductor structure comprising a semiconductor substrate having a U-shape trench, a U-shape gate dielectric layer on the U-shape trench, a U-shape gate region on the U-shape gate dielectric layer, a conducting matter in the U-shape gate region, and a cover dielectric layer on the conducting matter. The semiconductor structure may have a minimized size and when recess channels are formed thereby, the integration is accordingly improved without suffering from the short channel effect. | 01-01-2009 |
20090001513 | Semiconductor structure - The present invention discloses a structure of a buried word line, which comprises a semiconductor substrate having a U-shape trench, a U-shape gate dielectric layer in the U-shape trench, a polysilicon layer on the U-shape gate dielectric layer, a conducting layer on the polysilicon layer, and a cover dielectric layer on the conducting layer. The semiconductor structure may have a minimized size and when recess channels are formed thereby, the integration is accordingly improved without suffering from the short channel effect. | 01-01-2009 |
20090008691 | DRAM STRUCTURE AND METHOD OF MAKING THE SAME - A DRAM structure has a substrate, a buried transistor with a fin structure, a trench capacitor, and a surface strap on the surface of the substrate. The surface strap is used to electrically connect a drain region to the trench capacitor. | 01-08-2009 |
20090061580 | METHOD OF FORMING FINFET DEVICE - The invention discloses a method of forming a finFET device. A hard mask layer is formed on an active area of a semiconductor substrate. A portion of the hard mask layer is etched to form a recess. A conformal gate defining layer is deposited on the recess and a tilt angle ion implantation process is performed. A part of the gate defining layer is removed to define a fin pattern. The fin pattern is subsequently transferred to the hard mask layer. The patterned hard mask layer having the fin pattern is utilized as an etching mask, and the semiconductor substrate is etched to form a fin structure. | 03-05-2009 |
20110092044 | METHOD FOR MANUFACTURING CAPACITOR LOWER ELECTRODES OF SEMICONDUCTOR MEMORY - A method for manufacturing capacitor lower electrodes includes a dielectric layer, a first silicon nitride layer and a hard mask layer; partially etching the hard mask layer, the first silicon nitride layer and the dielectric layer to form a plurality of concave portions; depositing a second silicon nitride layer onto the hard mask layer and into the concave portions; partially etching the second silicon nitride layer, the hard mask layer and the dielectric layer to form a plurality of trenches; forming a capacitor lower electrode within each trench and partially etching the first silicon nitride layer, the second silicon nitride layer, the dielectric layer and the capacitor lower electrodes to form an etching area; and etching and removing the dielectric layer from the etching area, thereby a periphery of each capacitor lower electrode is surrounded and attached to by the second silicon nitride layer. | 04-21-2011 |
20110127574 | DEVICE FOR PREVENTING CURRENT-LEAKAGE - A device for preventing current-leakage is located between a transistor and a capacitor of a memory cell. The two terminals of the device for preventing current-leakage are respectively connected with a slave terminal of the transistor and an electric pole of the capacitor. The device for preventing current-leakage has at least two p-n junctions. The device for preventing current-leakage is a lateral silicon controlled rectifier, a diode for alternating current, or a silicon controlled rectifier. By utilizing the driving characteristic of the device for preventing current-leakage, electric charge stored in the capacitor hardly passes through the device for preventing current-leakage when the transistor is turned off to improve the current-leakage problem. | 06-02-2011 |
20110260230 | CELL WITH SURROUNDING WORD LINE STRUCTURES AND MANUFACTURING METHOD THEREOF - A memory cell with surrounding word line structures includes an active area; a plurality of first trenches formed on the active area in a first direction, each first trench has a bit line on a sidewall therein; a plurality of second trenches formed on the active area in a second direction, each second trench has two word lines formed correspondingly on the sidewalls in the second trench; and a plurality of transistors formed on the active area. The word line pairs are arranged into a surrounding word line structure. The transistor is controlled by the bit line and the two word lines, thus improving the speed of the transistor. | 10-27-2011 |
20120012907 | Memory layout structure and memory structure - A memory layout structure is disclosed, in which, a lengthwise direction of each active area and each row of active areas form an included angle not equal to zero and not equal to 90 degrees, bit lines and word lines cross over each other above the active areas, the bit lines are each disposed above a row of active areas, bit line contact plugs or node contact plugs may be each disposed entirely on an source/drain region, or partially on the source/drain region and partially extend downward along a sidewall (edge wall) of the substrate of the active area to carry out a sidewall contact. Self-aligned node contact plugs are each disposed between two adjacent bit lines and between two adjacent word lines. | 01-19-2012 |
20120168857 | Memory structure having a floating body and method for fabricating the same - A memory structure having a floating body is provided, which includes a substrate including an active area and an isolation structure surrounding the active area, a first source/drain region in the substrate in the active area, a first floating body in the substrate above the first source/drain region, a second floating body on the first floating body, a second source/drain region on the second floating body, and a trench-type gate structure in the substrate and beside the first floating body. A method of fabricating a memory structure having a floating body is also provided. | 07-05-2012 |
20130026554 | NAND TYPE FLASH MEMORY FOR INCREASING DATA READ/WRITE RELIABILITY - A NAND type flash memory for increasing data read/write reliability includes a semiconductor substrate unit, a base unit, and a plurality of data storage units. The semiconductor substrate unit includes a semiconductor substrate. The base unit includes a first dielectric layer formed on the semiconductor substrate. The data storage units are adjacent to each other and formed on the first dielectric layer. Each data storage unit includes at least two floating gates formed on the first dielectric layer, a second dielectric layer formed on the first dielectric layer and between the two floating gates, an inter-gate dielectric layer formed on the two floating gates and the second dielectric layer, at least one control gate formed on the inter-gate dielectric layer, and a third dielectric layer formed on the first dielectric layer and surrounding and tightly connecting with the two floating gates, the inter-gate dielectric layer, and the control gate. | 01-31-2013 |
20130026556 | NAND TYPE FLASH MEMORY FOR INCREASING DATA READ/WRITE RELIABILITY - A NAND type flash memory for increasing data read/write reliability includes a semiconductor substrate unit, a base unit, and a plurality of data storage units. The semiconductor substrate unit includes a semiconductor substrate. The base unit includes a first dielectric layer formed on the semiconductor substrate. The data storage units are formed on the first dielectric layer. Each data storage unit includes two floating gates formed on the first dielectric layer, two inter-gate dielectric layers respectively formed on the two floating gates, two control gates respectively formed on the two inter-gate dielectric layers, a second dielectric layer formed on the first dielectric layer, between the two floating gates, between the two inter-gate dielectric layers, and between the two control gates, and a third dielectric layer formed on the first dielectric layer and surrounding and connecting with the two floating gates, the two inter-gate dielectric layers, and the two control gates. | 01-31-2013 |
20130029465 | MANUFACTURING METHOD OF MEMORY STRUCTURE - The instant disclosure relates to a manufacturing method of memory structure for dynamic random-access memory (DRAM). The method includes the steps of: (a) providing a substrate having a plurality of parallel trenches formed on a planar surface thereof each defining a buried gate, where a first insulating layer is formed on the planar surface of the substrate; (b) forming a gate oxide layer on the surface of each trench that defines the buried gate; (c) disposing a metal filler on the gate oxide layer to fill each of the trenches; (d) removing the metal filler in the upper region of each trench to selectively expose the gate oxide layer; (e) implanting ions at an oblique angle toward the exposed portions of the gate oxide layer in each trench to respectively form a drain electrode and a source electrode in the substrate abreast the gate oxide layer. | 01-31-2013 |
20130059442 | METHOD FOR ADJUSTING TRENCH DEPTH OF SUBSTRATE - A method for adjusting the trench depth of a substrate has the steps as follows. Forming a patterned covering layer on the substrate, wherein the patterned covering layer defines a wider spacing and a narrower spacing. Forming a wider buffering layer arranged in the wider spacing and a narrower buffering layer arranged in the narrower spacing. The thickness of the narrower buffering layer is thinner than the wider buffering layer. Implementing dry etching process to make the substrate corresponding to the wider and the narrower buffering layers form a plurality of trenches. When etching the wider and the narrower buffering layers, the narrower buffering layer is removed firstly, so that the substrate corresponding to the narrower buffering layer will be etched early than the substrate corresponding to the wider buffering layer. | 03-07-2013 |
20130062674 | SPIN TRANSFER TORQUE RANDOM ACCESS MEMORY - A spin transfer torque random access memory includes a substance unit, a source line unit, an insulation unit, a transistor unit, a MTJ unit, and a bit line unit. The substance unit includes a substance layer. The source line unit includes a plurality of source lines formed inside the substance layer. The transistor unit includes a plurality of transistors respectively disposed on the source lines. Each transistor includes a source region formed on each corresponding source line, a drain region formed above the source region, a channel region formed between the source region and the drain region, and a surrounding gate region surrounding the source region, the drain region, and the channel region. The MTJ unit includes a plurality of MTJ structures respectively disposed on the transistors. The bit line unit includes at least one bit line disposed on the MTJ unit. | 03-14-2013 |
20130062676 | FLASH MEMORY STRUCTURE - A flash memory structure includes a semiconductor substrate, a gate dielectric layer on the semiconductor substrate, a floating gate on the gate dielectric layer, a capacitor dielectric layer conformally covering the floating gate, wherein the capacitor dielectric layer forms a top surface and four sidewall surfaces; and an isolated conductive cap layer covering the top surface and the four sidewall surfaces. | 03-14-2013 |
20130113110 | Semiconductor Structure Having Lateral Through Silicon Via And Manufacturing Method Thereof - The present invention provides a semiconductor structure having a lateral TSV and a manufacturing method thereof. The semiconductor structure includes a chip having an active side, a back side disposed opposite to the active side, and a lateral side disposed between the active side and the back side. The chip further includes a contact pad, a lateral TSV and a patterned conductive layer. The contact pad is disposed on the active side. The lateral TSV is disposed on the lateral side. The patterned conductive layer is disposed on the active side and is electrically connected to the lateral TSV and the contact pad. | 05-09-2013 |
20130119448 | MEMORY LAYOUT STRUCTURE AND MEMORY STRUCTURE - A memory array layout includes an active region array having a plurality of active regions, wherein the active regions are arranged alternatively along a second direction and parts of the side of the adjacent active regions are overlapped along a second direction; a plurality of first doped region, wherein each first doped region is disposed in a middle region; a plurality of second doped region, wherein each second doped region is disposed in a distal end region respectively; a plurality of recessed gate structures; a plurality of word lines electrically connected to each recessed gate structure respectively; a plurality of digit lines electrically connected to the first doped region respectively; and a plurality of capacitors electrically connected to each second doped region respectively. | 05-16-2013 |
20130140620 | Flash Memory and Manufacturing Method Thereof - The present invention discloses a flash memory. The flash memory includes a substrate and a memory string, a plurality of landing pads, a plurality of common source lines, a plurality of bit line contacts and at least a bit line, which are disposed on the substrate in sequence. The memory string includes a plurality of storage transistors. The landing pads are disposed between each of the storage transistors. The common source lines and the bit line contact are electrically connected to the landing pads alternatively. The common line is disposed on the common line contacts and is electrically connected thereto. The present invention further provides a manufacturing method of making the same. | 06-06-2013 |
20130146954 | Method Of Memory Array And Structure Form - The present invention provides a memory array including a substrate, an isolation region, a plurality of active regions, a plurality of buried bit lines, a plurality of word lines, a plurality of drain regions and a plurality of capacitors. The isolation region and the active regions are disposed in the substrate and the active regions are encompassed and isolated by the isolation region. The buried bit lines are disposed in the substrate and extend in the second direction. The word lines are disposed in the substrate extend in the first direction. The drain regions are disposed in the active region not covered by the word lines. The capacitors are disposed on the substrate and electrically connected to the drain regions. | 06-13-2013 |
20130168751 | HIGH-K METAL GATE RANDOM ACCESS MEMORY - The instant disclosure relates to a high-k metal gate random access memory. The memory includes a substrate, a plurality of bit line units, source regions, gate structures, drain regions, word line units, and capacitance units. The substrate has a plurality of trenches, and the bit line units are arranged on the substrate. The source regions are disposed on the bit line units, and the gate structures are disposed on the source regions. Each gate structure has a metal gate and a channel area formed therein. The gate structures are topped with the drain regions. The word lines units are arranged between the source and drain regions The capacitance units are disposed on the drain regions. Another memory is also disclosed, where each drain region and a portion of each gate structure are disposed in the respective capacitance unit, with the drain region being a lower electrode layer. | 07-04-2013 |
20130168801 | METHOD OF FORMING ISOLATION AREA AND STRUCTURE THEREOF - The instant disclosure relates to a method of forming an isolation area. The method includes the steps of: providing a substrate having a first type of ion dopants, where the substrate has a plurality of trenches formed on the cell areas and the isolation area between the cell areas of the substrate, with the side walls of the trenches having an oxidation layer formed thereon and the trenches are filled with a metallic structure; removing the metallic structure from the trenches of the isolation area; implanting a second type of ions into the substrate under the trenches of the isolation area; and filling all the trenches with an insulating structure, where the trenches of the isolation area are filled up fully by the insulating structure to form a non-metallic isolation area. | 07-04-2013 |
20130168811 | CAPACITOR HAVING MULTI-LAYERED ELECTRODES - The instant disclosure relates to a capacitor having multi-layered electrodes. The capacitor includes a dielectric layer having a first surface and a second surface oppositely arranged, a first electrode formed on the first surface, and a second electrode formed on the second surface. At least one of the first and second electrodes having a low band gap material layer formed on the dielectric layer and a conducting layer formed on the low band gap material layer. The band gap of the low band gap material layer is lower than the band gap of the conducting layer. | 07-04-2013 |
20130168812 | MEMORY CAPACITOR HAVING A ROBUST MOAT AND MANUFACTURING METHOD THEREOF - A manufacturing method for memory capacitor having a robust moat, comprising the steps of: providing a substrate; forming a patterned sacrificial layer on the substrate having a moat to separate a cell area and a peripheral area; forming a supporting layer on the sacrificial layer and filling the moat to form a annular member, wherein the supporting layer and the sacrificial layer arranged in alignment to form a stack structure; forming a plurality row of capacitor trenches on the substrate, wherein the capacitor trenches are formed at intervals in the stack structure; and forming a conducting layer on the supporting layer and covering the substrate and the inner surface of the stack structure defining the capacitor trenches. | 07-04-2013 |
20130203232 | MANUFACTURING METHOD OF RANDOM ACCESS MEMORY - A manufacturing method of a random access memory includes the following steps: providing a semiconductor structure having an array region and a peripheral region; forming a plurality of first trenches in the array region, and concurrently, a plurality of second trenches on the peripheral region; forming a polysilicon layer to cover the array region and the peripheral region, and the first and the second trenches are filled up with the polysilicon layer; planarizing the polysilicon layer so the remaining polysilicon layer only resides in the first and the second trenches; forming a conductive layer on the semiconductor structure; patterning the conductive layer to form a plurality of landing pads on the array region, and a plurality of bit line units on the peripheral region; and forming a plurality of capacitor units which is in electrical connection to the landing pads. | 08-08-2013 |
20130203233 | MANUFACTURING METHOD OF MEMORY CAPACITOR WITHOUT MOAT STRUCTURE - A manufacturing method of a memory capacitor without a moat structure includes the steps of: providing a semiconductor substrate defined with an array region and a peripheral region; forming a first oxidized layer on the array region; forming a second oxidized layer on the peripheral region; planarizing the first and the second oxidized layers; forming an insulating layer on the first and the second oxidized layers; forming a plurality of trenches on the array region, where the trenches pass through the first oxidized layer and the insulating layer on the first oxidized layer; forming a conductive layer on the side and base surfaces of each trench; removing a portion of the conductive layer and a portion of the insulating layer to form a plurality of notches to expose the first oxidized layer; and removing the first oxidized layers which are exposed from the notches. | 08-08-2013 |
20140110818 | RANDOM ACCESS MEMORY DEVICE AND MANUFACTURING METHOD FOR NODES THEREOF - A manufacturing method for the nodes of the RAM device, includes the steps as follows: forming a STI layer on a substrate to divide the substrate into several active areas; sequentially forming a first insulating layer and a hard mask layer on the substrate; etching the first insulating layer to form a first hole for exposing the STI layer and partial of the active areas; filling a conductive material in the first hole to form a conductor; forming a protective layer on the top surface of the conductor, wherein each protective layer has an opening aligning the STI layer; etching the conductor from the opening until the STI layer to form a second hole for exposing the STI layer, wherein each conductor is divided into two nodes by the second hole arranged therebetween; and forming a second insulating layer in the second hole for electrically isolating the nodes. | 04-24-2014 |
20140117442 | SEMICONDUCTOR STRUCTURE - A semiconductor structure includes multiple buried gates which are disposed in a substrate and have a first source and a second source, an interlayer dielectric layer covering the multiple buried gates and the substrate as well as a core dual damascene plug including a first plug, a second plug and an insulating slot. The insulating slot is disposed between the first plug and the second plug so that the first plug and the second plug are mutually electrically insulated. The first plug and the second plug respectively penetrate the interlayer dielectric layer and are respectively electrically connected to the first source and the second source. | 05-01-2014 |
20140124844 | SEMICONDUCTOR LAYOUT STRUCTURE - A semiconductor layout structure includes multiple active blocks which are disposed on a substrate, parallel with one another and extending along a first direction, multiple first shallow trench isolations which are disposed on a substrate, parallel with one another and respectively disposed on the multiple active blocks, and multiple second shallow trench isolations which are disposed on a substrate, cutting through multiple active blocks and extending along a second direction. The first direction has an angle about 1 degree to about 53 degrees to the second direction. | 05-08-2014 |
20140252550 | STACK CAPACITOR STRUCTURE AND MANUFACTURING METHOD THEREOF - The present invention provides a stack capacitor structure and a manufacturing method thereof, adapted for a random access memory. The stack capacitor structure is formed on a semiconductor substrate. The stack capacitor structure includes an oxide layer and a circular-shaped stopping layer. The oxide layer is disposed on the semiconductor substrate. The oxide layer has a capacitor trench therein. The circular-shaped stopping layer surrounds an edge of an opening of the capacitor trench. The disclosed stack capacitor structure and the manufacturing method thereof may thereby prevent the occurrence of the stack capacitor structure from having CD variation and belly region causing cell to cell leakage as result of manufacturing process limitation. | 09-11-2014 |
20140291729 | MEMORY UNIT, MEMORY UNIT ARRAY AND METHOD OF MANUFACTURING THE SAME - A memory unit includes a substrate, at least one charge storage element, at least one first recessed access element, and an isolation portion. The substrate has a surface and the first recessed access element is disposed in an active area of the substrate and extending from the surface into the substrate. The first recessed access element is electrically connected to the charge storage element and induces in the substrate a first depletion region. The isolation portion is adjacent to the active area and extending from the surface into the substrate. The isolation portion includes a trenched isolating barrier and a second recessed access element. The second recessed access element is disposed in the trenched isolating barrier and induces in the substrate a second depletion region merging with the first depletion region. | 10-02-2014 |
20140291738 | SEMICONDUCTOR DEVICE AND MANUFACTURING METHOD THEREFOR - A semiconductor electronic device structure includes an active area array disposed in a substrate, an isolation structure, a plurality of recessed gate structures, a plurality of word lines, and a plurality of bit lines. The active area array a plurality of active area columns and a plurality of active area rows, defining an array of active areas. The substrate has two recesses formed at the central region thereof. Each recessed gate structure is respectively disposed in the recess. A protruding structure is formed on the substrate in each recess. A STI structure of the isolation structure is arranged between each pair of adjacent active area rows. Word lines are disposed in the substrate, each electrically connecting the gate structures there-under. Bit lines are disposed above the active areas, forming a crossing pattern with the word lines. | 10-02-2014 |
20140291754 | SEMICONDUCTOR STRUCTURE HAVING BURIED WORD LINE AND METHOD OF MANUFACTURING THE SAME - A semiconductor structure having buried word line formed in a trench in a semiconductor substrate includes a gate oxide layer, a gate conductor, a gate cap layer, a blocking layer, and an isolation structure. The gate oxide layer is formed on the inner surface of the trench, the gate conductor is formed in the trench, and the gate cap layer is formed on the gate conductor. The blocking layer surrounds a bottom portion of the gate conductor, and the bottom portion of the gate conductor is isolated from the gate oxide layer by the blocking layer. The isolation structure surrounds a top portion of the gate conductor and in contact with the top end of the blocking layer. The top portion of the gate conductor is isolated from the gate oxide layer and the from the gate cap layer by the isolation structure. | 10-02-2014 |
20140308807 | METHOD FOR FABRICATING A SEMICONDUCTOR MEMORY - A method for fabricating a semiconductor memory includes the following steps. Active areas are defined in a substrate. An oxide layer is then formed on the active areas. The oxide layer is subjected to a surface treatment. A first polysilicon layer, a buffer layer and a hard mask are deposited. Recessed access devices are formed in an array region of the substrate. After the recessed access devices are formed, the hard mask and the buffer layer are removed to thereby form transistors in a peripheral region. A second polysilicon layer is deposited on the first polysilicon layer. The first and second polysilicon layers are then etched into a gate structure. | 10-16-2014 |
20140312460 | STACKED CAPACITOR STRUCTURE AND A FABRICATING METHOD FOR FABRICATING THE SAME - A stacked capacitor structure of the instant disclosure comprises a substrate and a plurality of stacked capacitors. The substrate has an insulating layer formed thereon and a plurality of contact plugs in the insulating layer, wherein the contact plugs are exposed on the upper surface of the insulating layer. Specially, each of the stacked capacitors comprises a lower electrode, a dielectric layer, and an upper electrode. The lower electrode is arranged on one of the contact plugs and has a columnar base portion and a crown shaped upper portion. The dielectric layer is arranged on the lower electrode and covers the outer surface of the lower electrode. The upper electrode is arranged above the lower electrode, wherein the dielectric layer is intermediately between the upper electrode and the lower electrode. | 10-23-2014 |
20150076696 | MEMORY DEVICE AND METHOD FOR MANUFACTURING THE SAME - A memory device comprises a substrate, a plurality of buried word lines, a plurality of digital contacts, a patterned insulating layer, a liner layer, a plurality of buried bit lines, and a cap layer. The buried word lines are arranged in the substrate in parallel along a first direction. Each of the digital contacts is arranged between one pair of the neighboring buried word lines. The patterned insulating layer is arranged on the buried word lines, having a plurality of contact holes opposite to the digital contacts. The liner layer is arranged on the substrate, and abuts the patterned insulating layer. The buried bit lines are arranged in parallel along a second direction different from the first direction. The cap layer arranged to cover the buried bit lines. | 03-19-2015 |